Annuloplasty Implant

ABSTRACT

A method of making an annuloplasty implant includes forming first and second support rings arranged in a coiled configuration around an axial direction and forming at least part of the first and second support ring from a carbon fiber material. The first and second support rings can be formed by 3-D printing according to dimensions of a 3-D reconstruction of a heart valve.

FIELD OF THE INVENTION

This invention pertains in general to the field of cardiac valvereplacement and repair. More particularly the invention relates to anannuloplasty implant, such as an annuloplasty ring or helix, forpositioning at the heart valve annulus and a method of manufacturing anannuloplasty implant.

BACKGROUND OF THE INVENTION

Diseased mitral and tricuspid valves frequently need replacement orrepair. The mitral and tricuspid valve leaflets or supporting chordaemay degenerate and weaken or the annulus may dilate leading to valveleak. Mitral and tricuspid valve replacement and repair are frequentlyperformed with aid of an annuloplasty ring, used to reduce the diameterof the annulus, or modify the geometry of the annulus in any other way,or aid as a generally supporting structure during the valve replacementor repair procedure.

A problem with prior art annuloplasty implants lack of flexibility ofthe implant in certain situations, which impedes optimal functioningwhen implanted in the moving heart, or adaptability to varyinganatomies. While the elastic properties are important, an annuloplastyimplant is also intended to function for years and years, so it iscritical with long term stability. Material fatigue may neverthelesslead to rupture of the material, which may be unexpected anduncontrolled. This entails a higher risk to the patient and it is thus afurther problem of prior art devices.

A further problem with prior art annuloplasty implants is the complexmanufacturing thereof. Annuloplasty implants may have to be manufacturedby time-consuming milling processes. Such manufacturing processes mayalso impede patient specific tailoring of the implants. The annuloplastyimplants are thus cumbersome to optimize to the anatomy of the specificpatient. This entails a higher risk to the patient and is thus a furtherproblem of prior art devices.

The above problems may have dire consequences for the patient and thehealth care system. Patient risk is increased.

Hence, an improved annuloplasty implant would be advantageous and inparticular allowing for avoiding more of the above mentioned problemsand compromises, and in particular allowing for improved accommodationto the valve anatomy, secure long-term functioning, and facilitatedmanufacturing and tailoring of the annuloplasty implant to varyinganatomies. A related manufacturing method would also be advantageous.

SUMMARY OF THE INVENTION

Accordingly, examples of the present invention preferably seek tomitigate, alleviate or eliminate one or more deficiencies, disadvantagesor issues in the art, such as the above-identified, singly or in anycombination by providing a device according to the appended patentclaims.

According to a first aspect an annuloplasty implant is providedcomprising first and second support rings arranged in a coiledconfiguration around an axial direction, and being adapted to bearranged on opposite sides of native heart valve leaflets to pinch saidleaflets. At least part of said first and second support ring is formedfrom a carbon fiber material. The first and second support rings areresiliently movable with respect to each other in opposite directionsalong said axial direction.

According to a second aspect a method of manufacturing an annuloplastyimplant is provided comprising forming first and second support ringsarranged in a coiled configuration around an axial direction, andforming at least part of said first and second support ring from acarbon fiber material.

According to a third aspect a method of manufacturing an annuloplastyimplant is provided comprising determining dimensions of an annuloplastyimplant based on a three-dimensional reconstruction of a heart valvedetermined from patient medical imaging data, forming first and secondsupport rings arranged in a coiled configuration around an axialdirection by three-dimensional printing for patient-specificmanufacturing of the annuloplasty implant according to said dimensions,wherein at least part of said first and second support ring is formed bydepositing a carbon fiber material in a layer by layer deposition bysaid three-dimensional printing.

Further examples of the invention are defined in the dependent claims,wherein features for the second and subsequent aspects are as for thefirst aspect mutatis mutandis.

Some examples of the disclosure provide for increased safety in case ofmaterial fatigue and rupture.

Some examples of the disclosure provide for securing long-termfunctioning and position of an annuloplasty implant.

Some examples of the disclosure provide for a more flexible implant.Some examples of the disclosure provide for improved accommodation of anannuloplasty implant to varying anatomies.

Some examples of the disclosure provide for facilitated tailoring of anannuloplasty implant to patient specific anatomies.

Some examples of the disclosure provide for facilitated manufacturing ofan annuloplasty implant.

Some examples of the disclosure provide for a less costly manufacturingof an annuloplasty implant.

It should be emphasized that the term “comprises/comprising” when usedin this specification is taken to specify the presence of statedfeatures, integers, steps or components but does not preclude thepresence or addition of one or more other features, integers, steps,components or groups thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other aspects, features and advantages of which embodiments ofthe invention are capable of will be apparent and elucidated from thefollowing description of embodiments of the present invention, referencebeing made to the accompanying drawings, in which

FIG. 1 is a schematic illustration of an annuloplasty implant accordingto one example;

FIG. 2 is a schematic illustration of an annuloplasty implant accordingto one example, positioned at a heart valve;

FIG. 3 is a schematic illustration of an annuloplasty implant accordingto one example;

FIG. 4 is a schematic illustration of an annuloplasty implant accordingto one example;

FIG. 5 is a schematic illustration of a method of manufacturing anannuloplasty implant according to one example;

FIG. 6 a is a schematic illustration of a cross-section of anannuloplasty implant according to one example;

FIG. 6 b is a schematic illustration of a cross-section of anannuloplasty implant according to one example;

FIGS. 7 a-c are schematic illustrations of cross-sections of anannuloplasty implant according to examples of the disclosure;

FIGS. 8 a-b are schematic illustrations of cross-sections of anannuloplasty implant according to examples of the disclosure;

FIG. 9 is a schematic illustration of a method of manufacturing anannuloplasty implant according to one example;

FIG. 10 a is a schematic illustration of an annuloplasty implant, in aside-view, according to one example;

FIG. 10 b is a schematic illustration of an annuloplasty implant, in atop-down view, according to one example;

FIG. 11 is a schematic illustration of a detail of an annuloplastyimplant according to one example;

FIG. 12 is a flow chart of a method of manufacturing an annuloplastyimplant according to one example; and

FIG. 13 is a flow chart of a method of manufacturing an annuloplastyimplant according to one example.

DESCRIPTION OF EMBODIMENTS

Specific embodiments of the invention will now be described withreference to the accompanying drawings. This invention may, however, beembodied in many different forms and should not be construed as limitedto the embodiments set forth herein; rather, these embodiments areprovided so that this disclosure will be thorough and complete, and willfully convey the scope of the invention to those skilled in the art. Theterminology used in the detailed description of the embodimentsillustrated in the accompanying drawings is not intended to be limitingof the invention. In the drawings, like numbers refer to like elements.

The following description focuses on an embodiment of the presentinvention applicable to cardiac valve implants such as annuloplastyrings. However, it will be appreciated that the invention is not limitedto this application but may be applied to many other annuloplastyimplants and cardiac valve implants including for example replacementvalves, and other medical implantable devices.

FIG. 1 schematically illustrates an annuloplasty implant 100 comprisinga first support ring 101 and a second support ring 102, being arrangedin a coiled configuration around an axial direction 103. The first andsecond support rings 101 and 102 are adapted to be arranged on oppositesides of native heart valve leaflets 104 to pinch said leaflets. FIG. 2illustrates the first and second support rings 101 and 102 arranged oneach side of the valve leaflets 104. At least part of the first andsecond support rings 101 and 102 is formed from a carbon fiber material105. The first and second support rings 101 and 102 are resilientlymovable with respect to each other in opposite directions 106, 106′,along said axial direction 103, as illustrated in FIG. 2 . Having atleast part of the first and second support rings 101 and 102 formed froma carbon fiber material 105 provides for advantageous flexiblecharacteristics between the first and second support rings 101 and 102in directions 106 and 106′, that allows for securely pinching the tissuebetween the rings 101 and 102 for secure fixation thereof, while beingsufficiently flexible to accommodate to movements of the beating heartas required, and thereby minimizing harmful interference with thesurrounding tissue. Long term functioning may thus be improved, with aminimized risk of damage to the tissue or the annuloplasty implant 100itself. Having at least part of the first and second support rings 101and 102 formed from a carbon fiber material 105 also provides for anannuloplasty implant 100 of reduced weight, and thereby reduced inertia,which allows for improved accommodation to the dynamics of the movementof the surrounding tissue, with reduced forces exerted on the valve andthe heart as a consequence. In addition to minimizing harmfulinterference with the heart, the reduced weight will also facilitatesecure fixation of the annuloplasty implant 100 to the heart valve, dueto the reduced forces associated with the movement of the annuloplastyimplant 100 when fixated to the valve. Having a coil- or helix-shapedannuloplasty implant 100 formed at least part from a carbon fibermaterial 105 thus provides for particularly synergistic effects inproviding a secure fixation—via improved pinching effect and reducedweight—and improved dynamical accommodation and long-term stability inthe heart. It is conceivable that the carbon fiber material 105, 105,may have shape-memory properties, such that the first and second supportrings 101 and 102 may assume an elongated configuration when deliveredin a catheter, whereupon the first and second support rings 101 and 102may assume the coiled configuration when ejected from the deliverycatheter.

The carbon fiber material 105 may comprise a first plurality carbonfibers 105 extending substantially in a longitudinal direction 107 ofthe first and/or second support rings 101 and 102 along an annularperiphery 114 thereof, as schematically illustrated in FIG. 1 . Thefirst and second support rings 101 and 102 are adapted to be resilientlymovable in perpendicular directions to the longitudinal direction 107 ofthe carbon fibers 105. I.e. the carbon fibers 105 may flex in transversedirections to the longitudinal direction 107. Having the carbon fibers105 extending in the longitudinal direction 107 may thus further improvethe elastic and flexible characteristics of the annuloplasty implant 100in e.g. the opposite directions 106, 106′, along the axial direction103, being substantially perpendicular to the longitudinal direction107. The first plurality carbon fibers 105 may extend substantially inthe longitudinal direction 107 of both the first and second supportrings 101 and 102 or only one of the first and second support rings 101and 102. The former case may provide for improved characteristics withthe advantages as discussed above.

The carbon fiber material 105 may comprise a weave 109 of carbon fibers,whereby a second plurality of carbon fibers 105′ extends substantiallyin a radial direction 108 perpendicular to the longitudinal direction107, as schematically illustrated in FIG. 4 . Having a weave 109 ofcarbon fibers 105, 105′, may provide for further improving themechanical characteristics of the annuloplasty implant 100. For example,the stiffness of the annuloplasty implant may be increased due to theinterwoven first and second plurality of carbon fibers 105, 105′.Alternatively, the second plurality of carbon fibers 105′ extendssubstantially in the radial direction 108 without being woven with thefirst plurality of carbon fibers 105, as schematically illustrated inFIG. 3 , i.e., providing for a layered structure of carbon fibers with afirst layer of longitudinally extending carbon fibers 105, and a secondlayer of radially extending carbon fibers 105′. The weave 109 or layeredstructure of carbon fibers 105, 105′, may be provided for both the firstand second support rings 101 and 102, or only one of the first andsecond support rings 101 and 102.

The carbon fiber material 105 may comprise a tubular braid 110 of carbonfibers extending along the first and second support rings 101 and 102.The tubular form of the braid 110 may be particularly advantageous inproviding structural integrity of the first and second support rings 101and 102. The braid 110 may be formed in a layered configuration where aplurality of tubular braids are arranged concentrically withinsuccessively reduced diameters. The number of layers of tubular braids110 may be varied to achieve desired mechanical properties of theannuloplasty implant 100 for customization to a particular application.

The first and/or second support rings 101 and 102 may comprise a corematerial 111 of a polymer material or metal alloy. The carbon fibermaterial 105 may then be at least partly arranged around a periphery 112of the core material 111, as schematically illustrated in FIG. 8 a . Thecarbon fiber material 105 may comprise longitudinally extending carbonfibers 105, or radially extending carbon fibers 105′, or a weave 109 ofcarbon fibers, or a tubular braid 110 of carbon fibers. By having a core111 of a secondary material such as a polymer material or metal alloy,the mechanical properties of the annuloplasty implant 100 can be furtheroptimized as desired to comply with a particular application. Having acore 111 of a secondary material may for example increase the structuralintegrity and stiffness of the annuloplasty implant 100. The corematerial 111 may also be more soft and/or flexible than the carbon fibermaterial 105, and the carbon fiber material 105 may be used to reinforcethe core 111 to achieve the desired properties. The core material 111may have shape-memory properties, such that the first and second supportrings 101 and 102 may assume an elongated configuration when deliveredin a catheter, whereupon the first and second rings 101 and 102 mayassume the coiled configuration when ejected from the delivery catheter.The carbon fiber material 105 may be circumferentially arranged aroundthe periphery 112 along both first and second rings 101 and 102 or alongonly one of the first and second rings 101 and 102. It is alsoconceivable that the carbon fiber material 105 may only be arrangedaround only part of the periphery 112.

The first and/or second support rings 101 and 102 may comprise a carbonfiber core 105, 105′, 109, 110, of a carbon fiber material, asillustrated in FIG. 8 b . A secondary material 111′ comprising a polymermaterial and/or a metal alloy may be at least partly arranged around aperiphery 112 of the carbon core material. Thus, the carbon fibermaterial 105, which may comprise longitudinally extending carbon fibers105, or radially extending carbon fibers 105′, or a weave 109 of carbonfibers, or a tubular braid 110 of carbon fibers, may be configured as asupporting core 111′ onto which the secondary material 111′ is arranged.It is conceivable that the secondary material 111′ may be abiodegradable material, which is absorbed in the body after some time,such as a temporary coating. The secondary material 111′ may also beporous or otherwise configured to be penetrated by e.g. sutures orclips, such as a textile or polymer material, for fastening theannuloplasty implant 100 to the tissue. The secondary material 111′ mayalso be configured to have a particularly low friction coefficient, suchas a Teflon-like material, to facilitate delivery through a catheter.The secondary material 111′ may comprise Dacron or similar materials.The secondary material 111′ may also comprise a flange or collarextending radially inwards and/or outwards with respect to the center ofthe support rings 101 and 102 to provide for a surface that can be usedfor suturing the implant 100 into position, and/or provide for sealingbetween the implant 100 and the tissue, and/or provide for a supportingflange against the leaflets in case of extending radially inwards asmentioned.

The carbon fiber material 105 may be interwoven with secondary fibers115 of a polymer material or a metal alloy, as schematically shown inFIG. 11 , illustrating a section of the annuloplasty implant 100, i.e. asection of a woven part of the annuloplasty implant 100 havingintertwined carbon fibers 105 and secondary fibers 115. The secondaryfibers 115 may be NiTinol strands or another biocompatible material. Thecombination of carbon fibers 105 and a secondary material 115 mayprovide for advantageous properties of the annuloplasty implant 100 interms of durability and flexibility.

The carbon fiber material 105 may comprise a layered carbon structureformed by three-dimensional printing of a plurality of carbon layers113, 113′. FIG. 5 schematically illustrates a three-dimensional printingprocess by a three-dimensional printing unit 400, depositing carbonlayers 113, 113′, on top of each other. The carbon layers 113, 113′, areschematically illustrated in FIG. 6 a , gradually building the shape ofthe annuloplasty ring 100. Three-dimensional printing of a layeredcarbon structure forming the first and second support rings 101 and 102provides for achieving a highly customizable annuloplasty implant 100,that can be easily adapted to various anatomies and manufactured ondemand. The carbon layers 113, 113′, forming the annuloplasty implant100 may be deposited and arranged in various configurations. FIG. 5merely illustrates one example, where the cross-section of theannuloplasty implant 100, defining the periphery of each layer 113,113′, is aligned in a certain angle relative to the longitudinaldirection of the support ring 102. In this case the cross-section has isrelatively small compared to the longitudinal extent of the support ring102. In the other extreme case, it is conceivable that the cross-sectionis aligned with an angle that is substantially parallel with thelongitudinal direction 107, such that each layer 113, 113′, extendsalong a substantial part of the longitudinal extent of the support ring102. FIG. 7 a illustrates one example where the layers 113, 113′, may beformed by depositing carbon fibers 105, 105′, in different orientationsin the plane of the layer 113, 113′. FIG. 7 a illustrates one example ofdepositing carbon fiber material 105 in a concentric annular pattern forforming a layer 113, whereas FIG. 7 c illustrates one example where thedeposition is off-set from the concentric pattern shown in FIG. 7 b .These are mere examples of carbon deposition patterns and it isconceivable that the carbon fiber material 105 may be deposited invarious configurations to build the layers 113, 113′, of theannuloplasty implant 100.

The annuloplasty implant 100 may comprise a laminate structure having aplurality of secondary layers 116, 116′, interposed between saidplurality of carbon layers 113, 113′, as illustrated in FIG. 6 b . Thelaminate structure may be provided by three-dimensional printing or byother layer-depositing processes. The laminate structure may provide forimproved strength of the annuloplasty implant 100 and the ability tocombine advantageous characteristics of different materials for theannuloplasty implant 100. The secondary layers 116, 116′, may be formedfrom a polymer material or a metal alloy.

Although the above annuloplasty implant 100 has primarily been describedas comprising first and second support rings 101 and 102 in a coiledconfiguration, it is conceivable that the advantageous properties andeffects provided for by the carbon fiber material 105 can also beutilized in annuloplasty rings comprising closed single-loop rings, suchas D-shaped rings, or open single-loop rings, such as C-shapedannuloplasty rings. A single-loop ring 100′ with a support ring 101comprising a carbon fiber material 105 is schematically illustrated inFIGS. 10 a -b, in a side-view and in a top-down view, respectively. Thefeatures described above with respect to the annuloplasty implant 100comprising first and second support rings 101 and 102 also applies tothe single loop-ring 100′. E.g. the ring 100′ may comprise carbon fibers105 arranged in the longitudinal direction, or carbon fibers 105′arranged in the radial direction, or a web 109 of carbon fibers, or atubular braid 110 of carbon fibers, a core 111 of secondary material 100or an outer covering 111′ of secondary material, a plurality of layers113, 113′, that may be deposited by three-dimensional printing,secondary layers 116, 116′, interposed between a plurality of carbonlayers etc.

FIG. 12 illustrates a method 200 of manufacturing an annuloplastyimplant 100. The order in which the steps of the method 200 areillustrated should not be construed as limiting and it is conceivablethat the order in which the steps of the method 200 is carried out maybe varied. The method 200 comprises forming 201 first 101 and second 102support rings arranged in a coiled configuration around an axialdirection 103, and forming 202 at least part of said first and secondsupport rings 101 and 102 from a carbon fiber material 105, 105′. Themethod 200 thus provides for an annuloplasty implant 100 with theadvantageous effects described above in relation to FIGS. 1-10 . Formingthe first and second support rings 101 and 102 may comprise depositing203 material in a layer by layer deposition by three-dimensionalprinting, as described above. The annuloplasty implant 100 may thus beproduced in an efficient and highly customizable manner, as furtherelucidated above. Depositing the material may comprise depositing 204layers 113, 113′, of said carbon fiber material 105, to provide for theadvantageous effects described above. Depositing the material maycomprise depositing 205 a secondary material 116, 116′, between thelayers of carbon fiber material, as described in relation to FIG. 6 b .The secondary material 116, 116′, may comprise a polymer material or ametal alloy.

The method 200 may comprise forming 206 the first and second supportrings 101 and 102 of a carbon fiber core 105, 105′, 109, 110, of carbonfiber material, and forming 207 a layer 111′ outside said core of asecondary material, as described in relation to FIG. 8 b above. Thesecondary material may be a polymer or metal alloy.

The method 200 may comprise forming 208 the first and second supportrings 101 and 102 of a core 111 of a secondary material, and forming 209a carbon fiber layer 105, 105′, 109, 110, outside the core of carbonfiber material. As mentioned, the secondary material may be a polymer ormetal alloy, and the carbon layer may comprise carbon fibers 105extending longitudinally, in the longitudinal direction 107, or carbonfibers 105′ extending in the radial direction 108, or a weave 109 ofcarbon fibers, or a tubular braiding 110 of carbon fibers.

Forming the first and second support rings 101 and 102 may compriseproviding 210 an elongate portion of the carbon fiber material, andforming 211 a coiled shape having the first and second support rings 101and 102 on a mold (not shown). The method may subsequently comprisefixating 212 the coiled shape, such as by a curing process, and removing213 the mold.

The method 200 may comprise determining 214 dimensions of theannuloplasty implant 100 based on a three-dimensional reconstruction ofa heart valve, such as a mitral valve, determined from patient medicalimaging data, such as MRI- or CT-scan medical imaging data. The method200 may then further comprise forming 215 the first and second rings101, 102, by three-dimensional printing for patient-specificmanufacturing of the annuloplasty implant 100 according to saiddimensions. The method 200 thus provides for a rapid process ofproviding a highly customizable annuloplasty implant 100, having thebenefits as elucidated above, to individual patients.

A method 300 is thus also provided, schematically illustrated in FIG. 13, comprising determining 301 dimensions of an annuloplasty implant 100based on a three-dimensional reconstruction of a heart valve determinedfrom patient medical imaging data, and forming 302 first 101 and second102 support rings arranged in a coiled configuration around an axialdirection 103 by three-dimensional printing for patient-specificmanufacturing of the annuloplasty implant 100 according to saiddimensions. At least part of said first and second support ring 101,102, is formed by depositing 303 a carbon fiber material 105, 105′, in alayer by layer deposition by said three-dimensional printing. Theadvantages of having a carbon fiber material as described above can thusbe provided while achieving a highly customizable method 300 ofmanufacturing the implant 100. FIGS. 5 and 9 are schematic illustrationsof the annuloplasty implant being manufactured according to any of themethods 200 or 300.

The present invention has been described above with reference tospecific embodiments. However, other embodiments than the abovedescribed are equally possible within the scope of the invention. Thedifferent features and steps of the invention may be combined in othercombinations than those described. The scope of the invention is onlylimited by the appended patent claims.

More generally, those skilled in the art will readily appreciate thatall parameters, dimensions, materials, and configurations describedherein are meant to be exemplary and that the actual parameters,dimensions, materials, and/or configurations will depend upon thespecific application or applications for which the teachings of thepresent invention is/are used.

1. A method of manufacturing an annuloplasty implant, said methodcomprising; forming first and second support rings arranged in a coiledconfiguration around an axial direction and forming at least part of thefirst and second support ring from a carbon fiber material.
 2. Themethod according to claim 1, wherein said forming the first and secondsupport rings comprises depositing material in a layer-by-layerdeposition by three-dimensional printing.
 3. The method according toclaim 2, further comprising: determining dimensions of the annuloplastyimplant based on a three-dimensional reconstruction of a heart valvedetermined from patient medical imaging data, and forming the first andsecond rings by the three-dimensional printing for patient-specificmanufacturing of the annuloplasty implant according to said dimensions.4. The method according to claim 2, wherein said depositing materialcomprises depositing layers of the carbon fiber material.
 5. The methodaccording to claim 4, wherein said depositing material comprisesdepositing a secondary material between the layers of carbon fibermaterial.
 6. The method according to claim 5, wherein the secondarymaterial comprises a polymer material or metal alloy.
 7. The methodaccording to claim 1, wherein said method comprises: forming the firstand second support rings of a carbon core of carbon fiber material, andforming a layer outside the core of a secondary material.
 8. The methodaccording to claim 7, wherein the secondary material comprises a polymermaterial or metal alloy.
 9. The method according to claim 1, whereinsaid method comprises: forming the first and second support rings of acore of a secondary material, and forming a carbon layer of carbon fibermaterial outside the core.
 10. The method according to claim 9, whereinthe secondary material comprises a polymer material or metal alloy. 11.The method according to claim 1, wherein said method comprisesinterweaving the carbon fiber material with secondary fibers of asecondary material.
 12. The method according to claim 11, wherein thesecondary material comprises a polymer material or metal alloy.
 13. Themethod according to claim 1, wherein said forming the first and secondsupport rings comprises; providing an elongate portion of the carbonfiber material, forming a coiled shape having the first and secondsupport rings on a mold, fixating the coiled shape, and removing themold.
 14. The method according to claim 1, wherein said method comprisesforming a weave of carbon fibers of the carbon fiber material.
 15. Themethod according to claim 1, wherein said method comprises forming atubular braid of carbon fibers of the carbon fiber material.
 16. Themethod according to claim 1, wherein said method comprises forming afirst plurality carbon fibers of the carbon fiber material extendingsubstantially in a longitudinal direction of the first and/or secondsupport ring along an annular periphery thereof so that the first andsecond support rings are resiliently movable in directions perpendicularto the longitudinal direction of the carbon fibers.
 17. The methodaccording to claim 16, further comprising forming a second plurality ofcarbon fibers extending substantially in a radial directionperpendicular to the longitudinal direction of the first and/or secondsupport ring.
 18. A method of manufacturing an annuloplasty implant,said method comprising: determining dimensions of an annuloplastyimplant based on a three-dimensional reconstruction of a heart valvedetermined from patient medical imaging data, and forming first andsecond support rings arranged in a coiled configuration around an axialdirection by three-dimensional printing for patient-specificmanufacturing of the annuloplasty implant according to said dimensions.19. The method according to claim 18, wherein at least part of the firstand second support ring is formed by depositing a carbon fiber materialin a layer-by-layer deposition by the three-dimensional printing.